8
Environmental Effect of Using Polluted Water in New/Old Fish Farms
Y. Hamed1, Sh. Salem2, A. Ali3 and A. Sheshtawi1 1Civil Engineering Department, Faculty of Engineering, Port Said University
2Ministry of Water Resources and Irrigation 3Irrigation and Hydraulics Department, Faculty of Engineering, Ain Shams University,
Egypt
1. Introduction
One of the most dangerous hazards affecting the environment situation in arid and semi-arid countries like Egypt is the water and soil pollution. Due to the lack of fresh water for irrigation, countries in arid and semi arid areas are forced to use marginal waters for irrigation and raising fish. The effect of using such kind of low quality water is rather dangerous on the environmental situation. Besides, countries like Egypt are facing great problems to get rid of untreated waste water and industrial disposal in addition to drainage water. The spill of such kind of waters in drains and lakes will cause great problems to the eco-system and environment in general. What will make the problem more complicated is the use of these waters for irrigation or raising fish due to lack of fresh waters. The using of polluted water in fish farms has a very dangerous environmental effect on soil and ground water. The water level in fish farms is higher than the original land level. Consequently, water flows from fish farms to the adjacent land and cause problems if the water was polluted. Bahr El-Baqar drain is considered as one of the most polluted drains in Egypt (Abdel-Shafy & Aly 2002). It receives and carries the greatest part of wastewater (about 3 BCM/year) into Lake Manzala through a very densely populated area of the Eastern Delta passing through four highly populated Governorates. Unfortunately, at the last decades, great areas on both sides of the drain were using its polluted water for irrigation and raising fish. As a polluted drain with high risk to the surrounding environment, Bahr El Baqar has received considerable concern by many scientists. Ali et al. (1993), Abdel-Azeem et al. (2007) studied the effect of prolonged use of drain water for irrigation on the total heavy metals content of south Port-Said city soils. They found that using such kind of water will cause high concentration of heavy metals in soil and plants roots and shots. Water quality, chemical composition, and hazardous effects on Lake Manzala water and living organisms caused by Bahr El-Baqar drain water has also been studied by several investigators like: Rashed & Holmes (1984), Khalil (1985) and Ezzat (1989). Special attention has been paid to the effect of environmental pollution from microbiological and toxicological points of view (Zaki 1994). Fish farms located on both sides of the Bahr El-Baqar drain are using the polluted water for rising fish since long time ago. Furthermore, many agricultural lands located in these areas are also using such kind of water for irrigation. The hazardous of such kind of water on
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environment is enormous. Not to mention to the fish itself coming from these farms. The fish production from these farms goes directly to the market. Consequently, the risk to the human health is very high.
Photo 1. Fish farms adjacent to Bahr El-Baqar drain in Egypt (From Hamed et al. 2011).
Hamed 2008, studied the effect of fish farms on both of soil structure and soil salinity in area near the study area of the current research and with the same type of soil (heavy clay soil). He used blue dye (food-grade Vitasyn-Blau AE 90 from Swedish Hoechst Ltd) mixed with water in order to test the soil structure properties. He found that fish farming does not contribute to decrease in the soil salinity. He concluded that increasing fish farming activities may lead to increasing soil salinity problems in agricultural lands. The results showed also that there is no evidence that soil properties are enhanced by fish farming. On the contrary, the soil nutrient state appears to be decreasing. A layer of 10 cm thickness of mud layer with cracks is formed at the surface when the farm dried (Photo 2.).
Photo 2. High amount of macropores and cracks at the mud layer accumulated at the surface In fish farm site (From Hamed 2008).
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Shang et al. (1998) concluded that extensive fish farming (shrimp) rapidly depleted the soil organic matter content. Other studies (Beverage & Phillips, 1993; Deb, 1998; Flaherty et al., 1999) have reported that intensive and semi-intensive fish farming result in high volume of organic and inorganic effluents and toxic chemicals to the ecosystem that gives hyper-nutrification, eutrophication, and high soil toxicity. In Bangladesh, studies have shown that fish farming destroys the mangrove forest, increases soil acidity, salinity (farmers use sea water), and water pollution (Deb, 1998; Guimaraes, 1989; Hossain et al., 2004 Rahman, 1994). Ali (2006) examined the impact of shrimp farming on rice ecosystem in a village in southwestern Bangladesh. He reported that prolonged shrimp farming using sea water for a 5-, 10-, and 15-year period increased soil salinity, acidity, and significantly degraded the area‘s soil quality. It also drastically reduced the rice production and destroyed the aquatic and non-aquatic habitat inherent in the rice ecosystem. A national project called El Salam Canal has recently finished. It relies on mixing water from the Damietta Branch of the Nile River with water from two major agricultural drains to be used for irrigation of 600,000 Feddan in the western side of Suez Canal and North Sinai. A total annual water requirement of 4.45 billion m3 of mixed water is required to irrigate 600,000 Feddan as follows: - 2.11 billionm3 fresh water from the Damietta branch, - 0.435 billionm3 drainage water from the Elserw drain, and - 1.905 billionm3 drainage water from the Bahr Hadous drain. The 200000 Feddan located within the service area of El Salam Canal in western part of Suez Canal spill their drainage water into Bahr El Baqar drain. Some agricultural areas located near the drain use El-Salam Canal water for irrigation. Due to the lack of the canal water, fish farms in the area forced to use other source of water. Unfortunately, the most easier source is the polluted Bahr El-Baqar drain. The objective of this chapter is to conduct an integrated environmental assessment for fish farms located adjacent to the most polluted drain in northeastern Egypt and use its water for raising fish. A comparison between the pollution level in new/old fish farms using polluted water and agricultural lands use the same kind of waters will be conducted. The comparison will include also agricultural lands using fresh water from El-Salam Canal, lands subjected to fill from the drain and moor lands which play a reference role. An investigation of the available clues of the problem include using another drain to decrease pollution will be conducted. The level of pollution in soil and water will be recorded as a result of using the polluted water from the drain for irrigation and raising fish. The problem of seepage from the drain to the adjacent fish farms or from fish farms to the adjacent lands will be investigated. In order to achieve that water and soil samples have been collected and analyzed in order to calculate the concentrations of five main heavy metals (Pb, Zn, Cd, Cu and Mn). Samples were collected from different depths ranging from 1m to 4m in 24 different locations for the study area. In order to conduct a complete integrated environmental assessment to the problem, different locations have been chosen in new/old fish farms, moor lands, fill lands and agricultural lands using polluted drain water and fresh water from the canal.
2. Locations of samples collected
The field experiments were conducted by Salem et al 2011 in year 2009 in area located at the last 20 km of the Bahr El Baqar drain before it spills its water in Manzala Lake. The study area consists of fish farms, agricultural lands, lands subjected to fill from the drain and moor
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lands. The area is located within the service area of the national project El Salam Canal south of Port Said city. Total of 24 boreholes were dug in 8 horizontal sections for different locations at the study area. Every horizontal section has length of 120-160 m from the Bahr El Baqar drain side and contains three boreholes. Fig 1, shows the location of the horizontal sections while Fig 2. shows the locations of the boreholes. Four sections were taken at each side of the drain. The depth of each borehole is 2-4 m. Five of boreholes were conducted in new/old fish farms. Three boreholes were conducted near the old fish farms (near the border of the farms). Six boreholes were conducted in moor lands and seven boreholes in fill land adjacent to the drain. Three boreholes were conducted in agricultural lands; two of them in agricultural land using the polluted water and one in agricultural land using fresh canal water. The agricultural land using fresh canal water has used polluted water from the drain for irrigation for 20 years and changed to use fresh water from the canal 5 years ago. The soil type in the study area is heavy clayey soil with more than 60% clay. Boreholes taken in moor lands will be used for comparison.
3. Soil/water samples
Two soil samples were collected from each borehole. Chemical analyses were carried out within 24 hr of sampling at the laboratory. The concentrations of six heavy metals (Pb, Zn, Cu,Mg, and Cd) were analyzed for each soil sample. Heavy metals were analyzed by the total adsorbed metals method according to USEPA (1986) using atomic spectrophotometer (model PYE UNICAM SP9, England). The fish farms and the agricultural lands in the area are supposed to use fresh water from El-Salam canal or its branches but due to water shortage especially in summer most of the lands use the drain water for irrigation or for raising fish. There is a branch drain called Sarhan drain parallel to Bahr El Baqar drain at the eastern side located 100 m far from the drain. It collects the drainage water from the area nearby and spills it again to Bahr El-Baqar drain. Boreholes were taken by rotary boring method at 8 sections, 4 sections at each side of Bahr El Baqar drain. Every section contains three bore holes. Two soil samples were taken from every borehole. One soil samples was taken above water table and the other taken under water table. The total depth of each borehole is 2-4 m. Table 1. shows locations and depths of boreholes. It shows also the type of land use of each borehole.
3.1 Results of water samples from the drain
Table (2) shows the concentrations of heavy metals for water samples taken from Bahr El Baqar drain at the same study area one year before the study was conducted (Hamed et al 2011). The results reflect the size of pollution of the drain water along the whole year.
3.2 Comparison due to land use
The objective of this section is to compare between new/old fish farms using polluted water and different land uses with different water quality used. The comparison will be between old fish farms, new fish farms, lands adjacent to old fish farms, agricultural lands use polluted water from the drain and agricultural lands use fresh water from Elsalam canal and fill resulted from the excavation of the drain sides and bottom and finally natural lands (moor).
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Sector Side
Pore
hole
Distance
From Bahr
El-Baqar
drain(m)
Symbol /
no.
Depth
(m) using
Water
table
depth
S1 right
S1b1 60 S1b1U 1.5 Old Fish
farm(10 years
old )
1.65 S1b1L 4
S1b2 142 S1b2U 1
land adjacent to
old fish farm 1.2
S1b2L 3
S1b3 162
S1b3U 1 New Fish
farm(two years
old )
1.3 S1b3dL 4
S2 right
S2b1 32.5
S2b1U 0.8 Old Fish
farm(10 years
old )
2.2 S2b2L 2.5
S2b2 65
S2b2U 0.7 Old Fish
farm(10 years
old )
2.5 S2b2L 2.75
S2b3 131
S2b3U 0.7 Fill from Sarhan
drain(5 years
old )
1.5 S2b3L 2
S3 left
S3b1 10
S3b1U 0.5 Fill from Bahr
El-Baqar drain
(15 years old )
0.7 S3b2L 2
S3b2 27 S3b2U 0.5
moor 0.85
S32b2L 1.5
S3b3 44 S3b3U 0.5
moor 1
S3b3L 1.5
S4 right
S4b1 35
S4b1U 0.5 Fill from Sarhan
drain (5 years
ago)
1 S4b1L 3
S4b2 70 S4b2U 1
moor 1
S4b2L 3.5
S4b3 106.5
S4b3U 1.5 Cultivated land
using El-salam
canal water
2.3 S4b3L 3.5
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S5 left
S5b1 35 S5b1U 1
Cultivated lands
using Bahr El-
Baqar drain
water
3.5
S5b2L 4
S5b2 72 S5b2U 1
land adjacent to
old fish farm 2.3
S5b2L 3
S5b3 120
S5b3U 0.5 New Fish
farm(two years
old )
0.7 S5b3L 3
S6 right
S6b1 35
S6b1U 0.5 Fill from Bahr
El-Baqar drain
(20 years old)
0.7 S6b2L 2
S6b2 67 S6b2U 0.5
moor 3.6
S6b2L 3.75
S6b3 114
S6b3U 0.5 Cultivated land
using Bahr El-
Baqar drain
1.75 S6b3L 2.5
S7 left
S7b1 35 S7b1U 1
moor 1
S7b1L 3
S7b2 63 S7b2U 0.8
moor 1
S7b2L 2
S7b3 73 S7b3U 0.5
land adjacent to
old fish farm 0.7
S7b3L 2
S8 left
S8b1 40
S8b1U 1 Fill from Bahr
El-Baqar drain
(15 years old)
2.25 S8b1L 2.75
S8b2 80
S8b2U 1 Fill from Bahr
El-Baqar drain
(15 years old)
2.75 S8b2L 3
S8b3 115
S8b3U 1 Fill from Bahr
El-Baqar drain
(20 years old)
1.9 S8b3L 2.2
Table 1. Locations and depths of boreholes and type of land uses (U: upper layer. L: lower
layer) (From Salem et al. 2011).
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ites
Concentration in mg/liter
Year 2008 Year 2009
Sep. Oct. Nov. Dec. Jan. Feb. Mar. Apr. Jul. Aug. Sep. Oct. Nov.
Cu 0.151 0.022 0.204 0.245 0.062 0.005 0.045 0.106 0.083 0.014 0.012 0.008 0.011
Pb 0.749 0.235 0.273 0.195 0.088 0.030 0.287 0.041 0.033 0.053 0.009 0.031 0.066
Zn 0.139 0.549 2.066 1.438 0.431 0.333 0.688 0.031 0.095 0.199 0.024 0.028 0.051
Cd 0.069 0.061 0.017 0.062 0.101 0.199 0.032 0.128 0.001 0.025 0.021 0.016 0.016
Mn 2.573 3.935 0.084 0.065 0.281 0.56 0.278 0.519 0.064 0.010 0.011 0.125 0.816
Table 2. The values of heavy metals in drain water for one year (From Hamed et al. 2011).
Fig. 1. Locations of the study area (From Salem et al. 2011).
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Fig. 2. Layout of the boreholes (From Salem et al. 2011).
Fig (3) shows the difference between the concentrations of heavy metals in samples of top
soil as a result of different land uses. The results showed that the old fish farms that used
Bahr El-Baqar drain water have the highest percentage of heavy metals. And the second
highest rate exists in the agricultural land irrigated with polluted water from Bahr El-Baqar
drain for along time. And the third highest concentration of heavy metals is in the land
adjacent to the fish farm that uses Bahr El-Baqar drain water. It indicates that the fish farms
using polluted water significantly affect the neighboring land.
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Next is land exposed to fill which exists only in top soil. In this case the concentration of
heavy metals depends mainly on the age of the fill and its original location. There are two
types of fill, fill comes from polluted Bahr-ElBaqar drain and fill comes from the agricultural
minor drain (Sarhan drain). For fill from Bahr El-Baqar drain, the concentration is decreased
with the increase of the fill age. The lowest concentration is for the fill has age of 20-25 years.
It could be attributed to the increase in pollution of the drain bottom soil by time. The
reason could be the increase in population and the increase in industry spread in the recent
decades which cause increase in untreated waste water and industrial disposal spilled into
the drain. In spit of the new fill comes from the relatively less polluted drain, Sarhan drain,
it has a high concentration ratio of heavy metals. It is known that Sarhan drain receives
drainage water from fish farms and agricultural lands using polluted water from Bahr El
Baqar drain for irrigation and raising fish.
Next are the new fish farms that used Bahr El-Baqar drain water, and finally, the lowest
heavy metal concentrations were found in both of the agricultural land uses fresh water
from ElSalam Canal and the natural lands (moor lands).
Fig (4) shows the difference between the concentrations of heavy metals in samples of
lower soil as a result of different land uses. Nearly the same results as in top soil were
obtained except for that the land adjacent to the fish farms which used Bahr El-Baqar
drain water has the highest percentage of heavy metals. This is a good proof that the fish
farms using polluted water significantly affect the neighboring land especially in lower
soil layers. The old fish farms that used Bahr El-Baqar drain water receive the second
highest rate in the concentrations of heavy metal. And the third highest concentration of
heavy metals is the agricultural land irrigated with water from Bahr El-Baqar drain for
along time, Next is the new fish farms that used Bahr El-Baqar drain water, and the finally
is the moor lands.
Comparison between upper samples due to land use
0
1
2
3
4
5
6
7
8
9
10
fish farm ( ten
years old)
fish farm ( two
years old )
Land adjacent
to fish farm
Cultivated
land using
Bahr El-Baqar
drain water
Cultivated
land using El-
salam Canal
water
Moor fill (fifteen
years old)
from Bahr El-
Baqar drain
fill (twenty
years old)
from Bahr El-
Baqar drain
fill (five years
old) from
Sarhan drain
Co
nc
en
tra
tio
n(
mg
/g)
pb
cu
Mn
Cd
Zn
Fig. 3. Mean heavy metals concentrations in upper soil samples for different land uses,
mg/liter (From Salem et al. 2011).
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Comparison between lower samples due to land use
0
1
2
3
4
5
6
7
8
fish farm ( ten years old) fish farm ( two years old) Land adjacent to fish
farm
Cultivated land using
Bahr El-Baqar drain
water
Cultivated land using El-
salam Canal water
Moor
Co
nc
en
tra
tio
n(
mg
/g)
pb
cu
Mn
Cd
Zn
Fig. 4. Mean heavy metals concentrations in lower soil samples for different land uses, mg/liter (From Salem et al. 2011).
3.3 Comparison due to location from Bahr El-Baqar drain
In the current section, comparison of new/old fish farms and other land uses will be investigated in details for each section and each borehole. Moreover, effect of seepage from the polluted drain or from fish farms to the adjacent lands will be studied. Boreholes were dug in different distances and locations in lands with different land uses. The distances from the drain were kept nearly constants for different sections. Here, the effect of minor drain (Sarhan drain) parallel to Bahr El-Baqar drain and at 100 m far will be investigated. There is a question needs to be answered, will the minor drain work as a defend barrier for seepage from the polluted drain to the lands located on the minor drain side? Will it affect the fish farms using polluted water? For the coming section, only the data for the lower soil layer will be used in order to investigate the seepage from the drain and fish farms. Fig (5) shows heavy metals concentrations of boreholes in section (1). It shows concentrations in boreholes S1b1, S1b2 and S1b3 located in old fish farms, land adjacent to old fish farms and new fish farms respectively. It is clear from the figure that the seepage factor from the main drain is not dominated here. The highest heavy metal concentrations are found in bore hole S1b2 (land adjacent to old fish farm) not in S1b1 the closest borehole to the main drain. The effect of the minor drain (Sarhan drain) is not clear here since borehole S1b2 has a high ratio of heavy metals concentration. It is probably due to the influence of pump station near the section. It seems that the type of land use is the dominated factor for the pollution concentration in this section. Fig (6) shows mean heavy metals concentrations of boreholes in section (2). It shows concentrations in boreholes S2b1, S2b2 and S2b3 located in old fish farms for the first two boreholes and fill from Sarhan drain for the third one. The highest heavy metal concentrations are found in borehole S2b2. Also, in this section it is clear that the seepage factor from the main drain is not dominated. The values of concentrations in old fish farm (10 years old) 65 m far from the drain are higher than that the corresponding values in old
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fish farms 32.5 m away. The pollution in fill from Sarhan drain (5 years old) is lesser than that in old fish farms. It is probably due to the high pollution accumulation in old fish farms and the fill location near Sarhan drain. Fig (7) shows heavy metals concentrations in section (3). It shows concentrations in boreholes S3b1, S3b2 and S3b3 located in fill from Bahr El Baqar drain for the first borehole and moor land for the second and the third ones. The dominated factor here is the land use factor. The higher value of concentration exists in second borehole. The ratio of concentration in this section is small compared with other sections. It is probably due to moor lands (natural land) which contain less amount of pollution and the low effect of drain seepage. In fill borehole, the effect of fill is small since the soil sample was taken in 2 m depth. Fig (8) shows heavy metals concentrations in section (4). It shows concentrations in boreholes S4b1, S4b2 and S4b3 located in fill from Sarhan drain (5 years ago), moor land and agricultural lands using water from ElSalam canal respectively. The ratio of concentration in this section is small compared with other sections. The seepage factor here also is not dominated. The less concentration is found in agricultural lands using water from ElSalam canal. The location of Sarhan drain adjacent to the agricultural lands could be another factor contributing for lower pollution concentration in its soil. Fig (9) shows heavy metals concentrations in section (5). It shows concentrations in boreholes S5b1, S5b2 and S5b3 located in cultivated lands using Bahr El-baqar drain water, land adjacent to old fish farm and New Fish farm (two years old) respectively. The higher concentrations of heavy metals are located in both of cultivated land with Bahr El baqar water and land adjacent to fish farms. These results reflect the bad effect of using polluted water for irrigation and the effect of fish farms on the adjacent lands. The relatively less concentration is located in new fish farms. However, only two years of fish farming using polluted water has raised the pollution concentration many times (see Fig (3) moor land and new fish farms). Fig (10) shows heavy metals concentrations in section (6). It shows concentrations in boreholes S6b1, S6b2 and S6b3 located in Fill from Bahr El-Baqar drain (20 years old), moor lands and cultivated land using Bahr El-Baqar drain respectively. Soil sample was taken at 2 m depth in fill borehole. Consequently, the effect of fill is small. The ratios of concentration in moor land are nearly the same as that for old fill from Bahr El Baqar drain. The unexpected results here are the lower ratio of concentration for cultivated land using Bahr El-Baqar drain although the soil sample was taken from the root zone area. It is probably due to the effect of Sarhan drain adjacent to the lands. However, the ratio of concentrations still relatively high compared with land using fresh water for irrigation. Again, seepage is not a dominated factor here. Fig (11) shows heavy metals concentrations in section (7). It shows concentrations in boreholes S7b1, S7b2 and S7b3 located in moor lands for the first two boreholes and in land adjacent to old fish farms for the third one. The effect of old fish farm on the lands nearby is quit clear here. The difference in heavy metals concentrations between land adjacent to fish farms and moor land is quite high. It reflects the damage effect of fish farms not only on its own soil but also on the soil nearby. It is probably due to the high polluted water level in fish farms which infiltrate to the adjacent lower level lands. Fig (12) shows heavy metals concentrations in section (8). It shows concentrations in boreholes S8b1, S8b2 and S8b3 located in fill from Bahr El-Baqar drain for 15, 15 and 20 years old respectively. Unlike other sections, seepage factor could be effective here. Another possible reason is the existence of some fill traces in deep layers.
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heavy metal in section 1
0
1
2
3
4
5
6
0 20 40 60 80 100 120 140 160 180
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 5. Heavy metals concentrations in section (1), mg/liter (From Salem et al. 2011).
heavy metal in section 2
0
2
4
6
8
10
12
0 20 40 60 80 100 120 140
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 6. Heavy metals concentrations in section (2), mg/liter (From Salem et al. 2011).
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heavy metal in section 3
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0 10 20 30 40 50
distance (m)
co
ncentr
ati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 7. Heavy metals concentrations in section (3), mg/liter (From Salem et al. 2011).
heavy metal in section 4
0
0.05
0.1
0.15
0.2
0.25
0.3
0 20 40 60 80 100 120
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 8. Heavy metals concentrations in section (4), mg/liter (From Salem et al. 2011).
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heavy metal in section 5
0
1
2
3
4
5
6
0 20 40 60 80 100 120 140
distance
co
ncen
trati
on
pb
cu
mn
cd
zn
Fig. 9. Heavy metals concentrations in section (5), mg/liter (From Salem et al. 2011).
heavy metal in section 6
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
0 20 40 60 80 100 120
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 10. Heavy metals concentrations in section (6), mg/liter (From Salem et al. 2011).
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heavy metal in section 7
0
2
4
6
8
10
12
0 10 20 30 40 50 60 70 80
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 11. Heavy metals concentrations in section (7), mg/liter (From Salem et al. 2011).
heavy metal in section 8
0
2
4
6
8
10
12
0 20 40 60 80 100 120 140
distance (m)
co
ncen
trati
on
(m
g/g
)
pb
cu
mn
cd
zn
Fig. 12. Heavy metals concentrations in section (8), mg/liter (From Salem et al. 2011).
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4. Summary and conclusions
In this chapter, an integrated environmental assessment has been conducted for fish farms using polluted water in area located within the service area of the most polluted drain in Egypt (Bahr el Baqar drain). The chapter focuses on two previous studies (Salem et al. 2011), (Hamed, et al. 2011). Total of 24 boreholes in 8 different sections on both sides of the drain have been dug in order to collect soil samples for depths ranging from 1 to 4 m. Samples were sent to the laboratory in order to measure the concentrations of five heavy metals (Pb, Zn, Cd, Cu and Mn). Boreholes were excavated in different land uses and in different spaces from the polluted drain in order to conduct an integrated comparison between fish farms using polluted water and other land uses. Results showed that the most polluted areas are the old fish farms (10 years old) using polluted water from the drain for raising fish and the land adjacent to it. It reflects the harmful effect of using polluted water for long time for raising fish not only on farms soil itself but also on the soil adjacent to the fish farms. Consequently, the pollution will reach fish produced from these farms and transferred to human affecting their health. Moreover, even in new fish farms with only less than two years old, the increase in heavy metals concentrations in soil is quite high during short period of time. The level of pollution in fish farms using polluted water is much more the level of pollution in agricultural lands using polluted water from the drain in irrigation. Both of fish farms and the agricultural lands have the same age in using polluted water from the drain. Also, the chapter warns about using polluted water for irrigation in agricultural lands. It proved the bad effect of such kind of water on soil and hence in plants since the digging depth is within the root zone (1-3). This conclusion will stand against those people supporting the use of polluted drain water for irrigation or for raising fish. Fill from both of Bahr ElBaqar drain and from agricultural drain (Sarhan drain) comes after as a third higher ratio of pollution. The quality of older fill from the polluted drain is better than the recent one. It is probably due to the increase in concentration of pollution by time in drain bottom soil. The difference in concentration is too high in a relatively short period of time. This reflects the rapid deterioration of the environmental situation for Bahr El Baqar drain by time. Since fish farms and agricultural lands using polluted water are using the minor drain (Sarhan drain) for drainage, the fill coming from this drain contains high ratio of heavy metals concentration. Unfortunately, many fish farms owners use such kind of fill for constructing banks around their farms. They use the fill also for increasing the level of their farms bed soil. For agricultural lands which have used polluted water for irrigation for long time (20 years) and changed to use fresh water for relatively less period of time (5 years), the improvement of its soil quality is quite clear. The decrease in heavy metals due to use of good quality of water is rather high. It will give an optimistic view for obtaining a clue for pollution in the area. Furthermore, the existing of minor drain parallel to the major polluted drain in relatively small distance (90-100m) contributes for reducing pollution for lands located after the minor drain in most cases. Consequently, as a current solution, the local government should force fish farms owners to use fresh water for washing their lands for long period of time before they use it again for fish farms. The Chapter revealed that the overall environmental situation at the area on both sides of the drain is quite dangerous. Five dangerous heavy metals with different concentrations
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have been found in each soil sample on surface or deep on the ground. This pollution hazardous level has its bad effect on both of fauna and flora at the area. Finally, the Chapter revealed that fish farming with polluted water has very bad consequences to the surrounding environment, not to mention to the fish itself. Moreover, previous studies have proved that the fish farming for long time with good quality water has a bad effect on the soil structure and soil salinity. Hence, we can imagine the level of environmental deterioration as a result of using polluted water in fish farming.
5. Acknowledgments
The field and publishing work was financially supported by the Swedish Research Council (SIDA) through a cooperation project between Suez Canal University, Port Said branch (Port Said University now) (Egypt) and Lund University (Sweden) under the title: "Sustainable use of Cairo waste water; environmental effects of the Bahr el Baqar Drain", in which Yasser Hamed is the principal investigator and Prof Atef Alam El-Din the University Vice President is the main supervisor.
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Recent Advances in Fish FarmsEdited by Dr. Faruk Aral
ISBN 978-953-307-759-8Hard cover, 250 pagesPublisher InTechPublished online 21, November, 2011Published in print edition November, 2011
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The world keeps changing. There are always risks associated with change. To make careful risk assessment itis always needed to re-evaluate the information according to new findings in research. Scientific knowledge isessential in determining the strategy for fish farming. This information should be updated and brought into linewith the required conditions of the farm. Therefore, books are one of the indispensable tools for following theresults in research and sources to draw information from. The chapters in this book include photos and figuresbased on scientific literature. Each section is labeled with references for readers to understand, figures, tablesand text. Another advantage of the book is the "systematic writing" style of each chapter. There are severalexisting scientific volumes that focus specially on fish farms. The book consists of twelve distinct chapters. Awide variety of scientists, researchers and other will benefit from this book.
How to referenceIn order to correctly reference this scholarly work, feel free to copy and paste the following:
Y. Hamed, Sh. Salem, A. Ali and A. Sheshtawi (2011). Environmental Effect of Using Polluted Water inNew/Old Fish Farms, Recent Advances in Fish Farms, Dr. Faruk Aral (Ed.), ISBN: 978-953-307-759-8, InTech,Available from: http://www.intechopen.com/books/recent-advances-in-fish-farms/environmental-effect-of-using-polluted-water-in-new-old-fish-farms
© 2011 The Author(s). Licensee IntechOpen. This is an open access articledistributed under the terms of the Creative Commons Attribution 3.0License, which permits unrestricted use, distribution, and reproduction inany medium, provided the original work is properly cited.